Dumbbell

ABSTRACT

A dumbbell with a selectable number of weight disks includes a handle with pins projectable in opposing directions, a base assembly for accommodating two sets of weight disks standing on edge and provided with openings. The projection lengths of the pins are stepwise selectable in order to permit selection of the number of weight disks supported on the handle. Neighbouring weight disks have mutually engaging connecting arrangements which axially interconnect the weight disks but which permit radial separation. The weight disks are planar with a circular, unbroken peripheral edge and with the openings located centrally. All connecting arrangements have a longitudinal centre line which coincides with a diameter line for the weight disks and with the permitted radial displacement direction between two neighbouring weight disks.

BACKGROUND AND SUMMARY

The present invention relates to a dumbbell with weight disks, where the number of weight disks on the dumbbell is selectable, and the weight disks may be accommodated standing upright in two sets in a base assembly, the weight disks having through-going openings which are located along a straight line with the weight disks standing in the base assembly, and the weight disks have mutually cooperating connecting means which are disposed, in an axial direction of the dumbbell, to interconnect neighbouring weight disks, but in a radial direction to permit separation of one weight disk from a neighbouring weight disk.

U.S. Pat. No. 6,416,466 shows, in FIGS. 4, 5, 7 and 9 a dumbbell with a number of weight plates standing upright in a base assembly. The weight plates display a highly irregular configuration and have a radial groove into the centre. Between the weight plates, there is disposed in the base assembly a handle, from which rods are extendable in opposing, axial directions.

The design and construction according to this United States Patent Specification is complex and entails that the position of the point of gravity for a combined dumbbell would probably be a considerable distance outside a longitudinal centre axis to the dumbbell. In addition, the radial grooves in the weight plates entail problems of a mechanical strength nature.

Further, the dumbbell according to this US Patent Specification has a U-shaped handle with a bottom which further entails that the point of gravity of the dumbbell is offset in the radial direction and which moreover may involve a hazard to the wrist of the user of the dumbbell if the dumbbell were to rotate in the hand holding it.

It is desirable to improve the dumbbell described by way of introduction in such a manner that the drawbacks inherent in the prior art dumbbells are obviated. In particular, it is desirable to design the weight disks included in the dumbbell such that they are satisfactory from the point of view of mechanical strength, that they will have their points of gravity more or less centred and that the dumbbell in its entirety will also be rotationally symmetrical, at least as regards the position of its point of gravity.

According to an aspect of the present invention, the dumbbell intimated by way of introduction is characterised in that the weight disks are in the form of substantially planar disks with a substantially circular unbroken peripheral edge and with the openings located centrally, that all connecting means have a longitudinal centre line which coincides with a diameter line for the weight disk, and that the permitted, radial displacement between two neighbouring weight disks substantially coincides with the centre line.

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

The present invention will now be described in greater detail hereinbelow, with reference to the accompanying Drawings. In the accompanying Drawings:

FIG. 1 is a perspective view of a base assembly in which is placed a handle included in a dumbbell and a set of weight disks which stand upright in the base assembly;

FIG. 2 shows the handle of FIG. 1, seen obliquely from beneath together with weight disks disposed on the handle;

FIG. 3 shows the base assembly of FIG. 1 in the partly cut-away state and without handle and weight disks;

FIG. 4 shows in the partly cut-away state the base assembly of FIG. 1 with a handle disposed therein and a set of weight disks;

FIG. 5 shows two different perspective views of a weight disk;

FIG. 6 shows a weight disk according to FIG. 5 in the partly cut-away state;

FIG. 7 is an exploded view showing a base assembly and a number of weight disks which are placed therein; and

FIG. 8 is an exploded view of a handle, however in a slightly modified version, the distal side in FIG. 8 being turned to face downwards in accordance with the arrow A when the handle lies in the base assembly.

DETAILED DESCRIPTION

In purely general terms, the dumbbell according to the present invention belongs to that category of dumbbell which has a selectable number of weight disks 1 which are fixable on a handle 2 and which are intended, standing upright, to be accommodated in corresponding accommodation spaces 3 in a base assembly 4. The dumbbell is designed in such a manner that it is possible to lift up from the base assembly the handle with a selectable number of weight disks fixed on the handle.

It will further be apparent from FIG. 1 that the handle 2 displays, at its opposing ends, housings 5 from which pin members 6 are disposed to be projectable in opposing directions in the longitudinal direction of the handle 2 and which are movable along the longitudinal centre axis of the handle. While not being apparent from FIG. 1 (see instead FIGS. 5, 6 and 7), the weight disks 1 have central openings 14 into which the pin members 6 are insertable. The purpose of the pin members is, by direct contact, abutment, to cooperate with and support the weight disks 1 when a dumbbell is lifted up out of the base assembly. In addition, the outer end sides of the housings 5 facing away from one another display connecting means 7 which are disposed for cooperation with corresponding connecting means 8 on the weight disks.

As is intimated in FIG. 1, the pin members 6 are suitably designed as solid rods of superior mechanical strength. Possibly, a tubular design may also come into consideration, in which event there may be accommodated interiorly in the pin members parts that are not described here. The free ends of the pin members are smooth, possibly slightly bevelled, and in this position lack transversely directed projecting parts such as, for example, flip-out locking devices so as to facilitate entry into the weight disks.

The connecting means are designed in such a manner that, in the axial direction, i.e. along a longitudinal centre axis to the handle, they interconnect neighbouring weight disks at the same time as they permit a radial displacement of one weight disk in relation to another (in FIG. 1 in the vertical direction, provided that the base assembly 4 rests on a horizontal substrate). The innermost weight disks are correspondingly interconnected to the connecting means 7 of the housings 5.

It follows from the foregoing that the number of weight disks which, in their central openings 14, have the pin members 6, can no longer carry out the radial movements, for which reason on lifting of the handle 2 out of the base assembly 4, this number of weight disks will accompany the handle up out of the base assembly.

The number of weight disks which is located outside the raised weight disks, and into whose central openings 14 the pin members 6 do not extend, is therefore not affected by the projecting pin members 6, for which reason these outer weight disks will remain in place in the base assembly 4.

In order to realise the above-considered axial projection of the pin members 6, there is disposed in the handle a screw mechanism which realises the axial projection or retraction of the pin members 6 when a rotary section 9 between the housings 5 of the handle is turned in relation to the housings about the longitudinal centre axis of the handle.

In order to define and/or display such projection lengths for the pin members 6 as correspond to a complete number of weight disks, the handle 2 of the dumbbell includes one or more indexing devices which will be described in greater detail hereinbelow. The purpose of the indexing device is thus to facilitate a gradual projection of the pin members 6 by correct step lengths.

It will be apparent from FIG. 8 that the handle has an inner tube 40 with two longitudinal apertures 41. The pin members 6 which, in this embodiment, are solid metal rods, are longitudinally displaceable interiorly in the inner tube 40 and have pins 42 which extend out through the apertures, whereby the pin members 6 are prevented from rotating in relation to the inner tube 40. Outside the inner tube 40, there is provided an outer tube 43 with two helical grooves, in which the pins 42 are accommodated. The above-described design and construction implies that when relative rotation takes place between the inner 40 and the outer 43 tubes, the pin members 6 will move axially in the longitudinal direction.

Outside the outer tube 43, there is disposed a rotary portion 9 which the user of the dumbbell manually twists when a choice is made of the number of weight disks 1 on the dumbbell.

The rotary portion 9 is rotationally interconnected with an index ring 45, which is included in the above-discussed indexing device and which displays, along its periphery, markings 46 for the number of weight disks to be accommodated on the dumbbell. The markings 46 are shown in an opening 47 in the outer casing 48 of the housings 5, the outer casing being positionally fixed in the direction of rotation when the dumbbell rests in the base assembly 4 and, moreover, the outer casing is rotationally interconnected with the inner tube 40.

It will be apparent from FIG. 3, which shows an embodiment modified in relation to that of FIG. 8, that the base assembly 4 has two seats 10 for accommodating and positionally fixing the housings 5 of the handle 2, in particular its outer casing 48. In addition, the base assembly 4 has, at its opposing ends, accommodation spaces 3 each for accommodating a set of weight disks 1. Furthermore, the end walls 11 of the base assembly 4 are provided with connecting means 12 for cooperation with the corresponding connecting means 8 on both of the outermost of the weight disks standing upright in the base assembly. Hereby, the weight disks will be positioned in the direction of rotation in relation to the base assembly 4.

The housings 5 and the seats 10 have mutually cooperating positioning means 38, 39 by means of which the handle 2 (apart from its gripping portion 9) is positioned in the direction of rotation about the longitudinal centre axis of the handle in relation to the base assembly when the handle is in position in the base assembly. This position of rotation defined in relation to the base assembly also implies that the connecting means 7 of the housings 5 are located in the correct position in relation to the connecting means of the weight disks when the weight disks stand upright in the base assembly, since the connecting means 8 of the outermost weight disks cooperate with the connecting means 12 on the end walls 11 of the base assembly. The positioning means are in the form of grooves 38 in the housings 5, and projections 39 in the seats 10 insertable in the grooves.

According to the present invention, it is possible to dispense with the positioning means 38 and 39, since the handle 2 of the assembly and the weight disks 1 are also aligned in the direction of rotation about the longitudinal centre axis of the dumbbell by cooperation between the connecting means 8 of the weight disks 1 and the connecting means 12 of the base assembly 4, or alternatively between corresponding connecting means on the weight disks.

It will be apparent from FIGS. 5 and 6 taken together that the weight disks are substantially circular, planar disks with central openings 14 for accommodating the pin members 6 on the handle 2. Furthermore, the weight disks 1 have substantially circular peripheral edges, which are unbroken and which extend throughout the entire periphery of the whole of the weight disk. Otherwise expressed, the central openings 14 have no communication whatever with the peripheral edges of the weight disks in the form of grooves, recesses or the like.

It will be further apparent from FIGS. 5 and 6 that the connecting means 8 of the weight disks 1 include a depression 16 on the one side of the weight disk and a corresponding projection 17 on the opposing side of the weight disk. Preferably, the projections 17 and the recesses 16 are complementary to one another, although this is not absolutely critically necessary. Both the projections and the recesses have a longitudinal centre line, which is also a diameter line for the weight disk through the central opening 14. In the longitudinal direction of this centre line, both the depressions 16 and the projections 17 are cuneiform, symmetrically about the longitudinal centre line. Further, the cross-sectional configuration in the depressions 16 is undercut, for example dovetailed, the projections 17 having a corresponding profile. This implies that when two weight disks are interconnected with the projection 17 on the one weight disk accommodated in the depression 16 on the other weight disk, the weight disks can no longer be displaced in the axial direction in relation to one another. On the other hand, they are displaceable only in one direction along the above-mentioned longitudinal centre line to the projection 17 and the depression 16. This longitudinal centre line is vertical when the weight disks are in position upright in the base assembly 4 (see FIG. 1) and in the direction of rotation are aligned by cooperation between the projections 17 of the outermost weight disk and the connecting means of the base assembly 4.

It will be apparent from FIGS. 1 and 7 that when the weight disks 1 are standing in the base assembly 4 or are just about to lifted up out of or deposited down into the base assembly, the widest ends of the projections 17 and recesses or depressions 16 are turned to face upwards, for which reason an inner weight disk 1 (located more proximal the handle 2) can always be lowered down into or lifted up out of an outer weight disk, as long as the pin members 6 do not extend through the central openings 14 in both of these weight disks.

It will be apparent from FIG. 2 that the housings 5 have a corresponding design of their connecting means 7, viz. projections 18, which may be said to correspond to a part of the projection 17 on a weight disk and which therefore fit into the depressions 16 on both of the innermost weight disks 1.

It will be apparent from FIG. 5 that the projection 17 on the weight disk has, in its narrower end, a change bevel 19 whose purpose is to facilitate insertion of the projection 17 in a corresponding depression 16 on an adjacent weight disk. It will further be apparent that the depression 16 is open all the way out to the peripheral edge of the weight disk so that the projection on an adjacent weight disk can thereby readily be passed down in the wider end 20 of a depression 16.

As was considered above, both of the pin members 6 are projectable in opposing axial directions from the handle 2 by rotation of the rotary portion 9 of the handle in relation to the housings 5 of the handle which, in the direction of rotation, is positionally fixed in the base assembly 4 via the projections 18 of the housings 5 and the depressions 16 and projections 17 of the weight disks 1, the projection 17 of the outermost weight disk being accommodated in the connecting means 12 of the base assembly 4. Since this axial projection takes place with the aid of a screw mechanism, the projection will be continuous as a function of the angle of rotation of the rotary portion 9. It will readily be perceived that only certain projection lengths of the pin members are desirable, namely such projection lengths as imply that the end surfaces 21 of the pin members 6 are located immediately inside an outer side of a weight disk 1 standing upright in the base assembly. Setting of such projection lengths is made possible or facilitated by the above mentioned indexing devices. With such a projection length, all weight disks inside the relevant weight disk in the radial direction will have complete support from the pin member 6 and the outermost weight disk has as good support as it is possible to achieve. On the other hand, the weight disk lying outside is wholly unaffected by the pin member 6.

In order to ensure that, on using a raised dumbbell, no relative rotation takes place between the rotary portion 9 and the weight disks connected to the housings 5, for example because of the flywheel effect of the weight disks, which might possibly entail that the pin members 6 are retracted to some extent, so that at least the outermost weight disks are free and will fall off the dumbbell, both of the housings 5 have locking means which, in selected projection lengths, lock the pin members in the axial direction as soon as the dumbbell is lifted out of the base assembly 4. To this end, both of the pin members 6 have a first series of recesses 22 (FIGS. 1 and 4), where the distance between adjacent recesses corresponds to the thickness of one weight disk 1. Interiorly in both of the housings 5, there are provided, as will be apparent from FIGS. 4 and 8, sliding portions 23 with openings through which the pin members 6 extend. The sliding portions 23 are spring-biased by means of springs 24 in a downward direction when the dumbbell rests in the base assembly 4. In such instance, the sliding portions 23 have edges which; under the action of the springs 24, strive to snap down into one of the recesses 22 so that, as a result, the pin members are locked in the axial direction as a result of the engagement between the recesses 22 and the sliding portions 23.

In order to permit outward pivoting of both of the pin members 6 when the dumbbell rests in the base assembly 4, blocking means are provided which block the locking function of the locking means, but which cease to function as soon as the dumbbell is lifted out of the base assembly 4. The blocking means are in the form of upstanding heels 25 which are disposed on the seats 10 in the base assembly 4. The heels 25 are disposed to extend in through openings 26 in the lower sides of the housings 5 when the housings rest in the seats 10 (FIG. 2). When the heels 25 in this manner extend in to the interior of the housings, they come into contact with lower end portions 27 on the above-mentioned sliding portions 23 so that these are lifted a sufficient distance against the action of the springs 24 to become disengaged from the recesses 22 of the pin members 6.

In the foregoing, it was mentioned that the projection of both of the pin members in the axial direction takes place in a continuous movement by rotation of the rotary portion 9 of the handle in relation to the housings 5. In order to obtain stepwise projection lengths of the pin members which correspond to the locking positions for the locking means and where, as was mentioned above, the end surfaces of the pin members are located immediately inside the outer sides of the relevant weight disks, the present invention includes, as was mentioned above, an indexing device which gives stepwise setting possibilities in the longitudinal direction of the pin members 6. This indexing device comprises a second series of recesses 28 on the pin members 6, where the distance between adjacent recesses in the first and the second series mutually corresponds and corresponds to the thickness of one weight disk. The recesses 28 in the second series have V-shaped or circular cross section in order to avoid an excessively powerful locking function. Interiorly in each one of the housings 5, there is further provided a snap portion 29 (FIG. 4) which, under the action of a spring (not shown in this Figure), is movable into engagement with one of the recesses 28. In such instance, the design and formation of the end of the snap portion 29 facing towards the pin members and the formation of the recesses 28 are such that an accurate stepwise projection of the pin members can take place without the resistance being excessively great on “unscrewing” of the pin members.

The snap portions 29 fulfil a further function, namely that of preventing lifting of the handle 2 out of the base assembly 4 when the pin members 6 are located in “incorrect” positions. It will be apparent from FIG. 2 that the housings 5 have openings 36 through which the snap portions 29 can extend out when the inner end regions of the snap portions are located in abutment against the pin members 6 between two of their recesses 28. When the snap portions 29 by such means extend outside the peripheries of the housings 5, their projecting portions will be accommodated in corresponding recesses 37 in the seats 10 of the base assembly 4 in order thereby to prevent lifting of the handle 2 out of the base assembly with incorrect projection lengths of the pin members 6.

FIG. 8 shows a slightly modified embodiment, where the one series of recesses 28, the snap portion 29, the opening 36 as well as the recess 37 are omitted. The correct projection length for the pin members 6 is realised in this embodiment in that there are disposed recesses 49 along the peripheries of the index rings 45 at equal spacing in the circumferential direction. On the seats, catch-shaped projections 50 are provided which, through openings from beneath, extend into the housings 5 when the dumbbell rests in the base assembly 4. The projections have shanks which are substantially parallel with the centre axis of the handle 2 and which grasp interiorly about the peripheral edge of the index rings 45. When these projections are located between the recesses 49 of the index rings 45, they prevent a lifting of the dumbbell up out of the base assembly 4.

When, on the other hand, the projections 50 are located in register with any of the recesses 49, lifting may take place. In such positions, the index ring 45, and thereby the gripping portion 9 and the outer tube 43 are in such positions of rotation that the outer end surfaces 21 of the pin members 6 are located immediately inside the outsides of two weight disks 1. That number of weight disks which is thus carried by the pin members 6 is displayed as a corresponding marking 46 in the opening 47 of the housing 5.

As is apparent from FIGS. 5 and 6, the weight disks are separate units which, apart from the connecting means 7 and 8, are not interconnected via any struts or rods, which is a common prior art practice when such struts or rods are used for pairwise interconnection of two weight disks, one at each end of the dumbbell. This implies that, according to the present invention, the space through 360° about the handle 2 is completely free throughout the entire length of the handle in principle between the connecting means 7 of the housings 5. This is a crucial feature in the subject matter of the present invention, since such connection struts or rods could hit and injure the wrist of a user if the dumbbell, because of its considerable flywheel effect, were to twist or pivot in the grip of the user.

According to the present invention, both of the pin members 6 are disposed coaxially, with a longitudinal centre line to the handle 2 and coaxially in relation to the circumferential surfaces of both of the housings 5. Since the openings 14 of the weight disks 1 are disposed coaxially with the peripheral edges 15 of the weight disks, the dumbbell, as thus far described, will be rotationally symmetrical as regards the position of the point of gravity.

It will be apparent from FIGS. 5 and 6, primarily FIG. 6, that each weight disk has a core 30 of a relatively heavy, first material and an outer layer 31 surrounding the core, of a second material. The core 30 comprises a substantially planar, relatively thin and circular disk 32 of metal, preferably steel, which has a central opening 33 which is coaxial with the central opening 14 of the weight disk and which may appropriately be slightly larger than it. On that side of the disk 32 where the depression 16 of the disk is disposed, there are secured substantially circle-segment shaped weight portions 34, which are of considerably greater thickness than the disk 32. In the radial direction, the weight portions 34 extend in to the immediate proximity of the longitudinal, slanting edges 35 which, on both sides, define the depression 16 of the weight disk. The relatively slight cuneiform configuration which the depressions 16 and the projections 17 have on the weight disk entails that the total point of gravity of the weight disk will but insignificantly deviate from the centre of the through-going opening 14. Further, the edges of the weight portions 34 facing towards the depressions 16 have a supporting effect against the opposing edges 35 of the depression.

The outer layer 31 of the weight disk is suitably manufactured by injection moulding of plastic around the core 30. This implies that the projections 17 of the weight disks also consist of or comprise plastic. Further, the central opening 14 is surrounded by a plastic layer. 

1. A dumbbell with weight disks, where the number of weight disks on the dumbbell is selectable, and the weight disks may be accommodated standing upright in two sets in a base assembly, the weight disks having through-going openings which are located along a straight line with the weight disks standing in the base assembly, and the weight disks have mutually cooperating connecting means which are disposed, in an axial direction of the dumbbell, to interconnect neighbouring weight disks, but in a radial direction to permit separation of a weight disk from a neighbouring weight disk, wherein the weight disks are in the form of substantially planar disks with a substantially circular unbroken peripheral edge and with the openings located centrally, that all connecting means have a longitudinal centre line which coincides with a diameter line for the weight disk, and with the permitted, radial displacement between two neighbouring weight disks.
 2. The dumbbell as claimed in claim 1, wherein the connecting means on each weight disk include a depression which is disposed on the one side of the weight disk, is cuneiform in the longitudinal direction and undercut in the transverse direction, and a projection disposed on the opposing side of the weight disk in register with the depression and substantially complementary thereto.
 3. The dumbbell as claimed in claim 2, wherein the depression is, at least at its wider end, open towards the peripheral edge of the weight disk.
 4. The dumbbell as claimed in, wherein the connecting means extend along substantially the whole of the diameter of the weight disk.
 5. The dumbbell as claimed in, wherein the weight disk is manufactured from at least one first material constituting a core in the weight disk and one second material, constituting a surface layer for the weight disk; and that the core also extends over that region of the weight disk where the weight disk displays its connecting means.
 6. The dumbbell as claimed in claim 5, wherein the core comprises a substantially circular disk and two substantially circle-segment shaped weight parts which are disposed thereon, and which are disposed on each side of the depression.
 7. The dumbbell as claimed in, wherein the undercut depression has a substantially dovetail-shaped cross section.
 8. The dumbbell as claimed in, wherein the weight disk has means for its positioning about its centre axis in relation to the base assembly; and that a plurality of weight disks in their thus established positions have their connecting means in engagement with one another; and that the centre lines of the connecting means are substantially vertical when the base assembly stands on a horizontal substrate.
 9. The dumbbell as claimed in, wherein all weight disks in a base assembly have the same configuration and that they are randomly interchangeable in position in the base assembly as well as being separate and discrete from one another.
 10. The dumbbell as claimed in claim 2, wherein the connecting means extend along substantially the whole of the diameter of the weight disk.
 11. The dumbbell as claimed in claim 2, wherein the weight disk is manufactured from at least one first material constituting a core in the weight disk and one second material, constituting a surface layer for the weight disk; and that the core also extends over that region of the weight disk where the weight disk displays its connecting means.
 12. The dumbbell as claimed in claim 11, wherein the core comprises a substantially circular disk and two substantially circle-segment shaped weight parts which are disposed thereon, and which are disposed on each side of the depression.
 13. The dumbbell as claimed in claim 2, wherein the undercut depression has a substantially dovetail-shaped cross section.
 14. The dumbbell as claimed in claim 2, wherein the weight disk has means for its positioning about its centre axis in relation to the base assembly; and that a plurality of weight disks in their thus established positions have their connecting means in engagement with one another; and that the centre lines of the connecting means are substantially vertical when the base assembly stands on a horizontal substrate.
 16. The dumbbell as claimed in claim 2, wherein all weight disks in a base assembly have the same configuration and that they are randomly interchangeable in position in the base assembly as well as being separate and discrete from one another. 